Abstract: Quality assurance device for calibrating and testing the accuracy of movement-correlated computed tomography (“4D CT”) target-locating systems has a test unit sub-assembly adapted to be combined with a dynamic phantom system. The test unit sub-assembly has an axially and rotationally moveable test rod slideably disposed inside of a substantially hollow fixed housing. A matrix of markers, or “fiducials”, are located in the wall of the housing. A single fiducial is located near the distal end of the moveable test rod. The distal end portion of the moveable test rod is adapted to be connected to a motion actuator, which is programmed to oscillate the test rod in a predetermined pattern. When the test unit sub-assembly is inserted into a tissue equivalent phantom member, the combined sub-assembly and phantom member can then be subjected to four-dimensional imaging to generate a visual image.

Abstract: Quality assurance device for calibrating and testing the accuracy of movement-correlated computed tomography (“4D CT”) target-locating systems has a test unit sub-assembly adapted to be combined with a dynamic phantom system. The test unit sub-assembly has an axially and rotationally moveable test rod slideably disposed inside of a substantially hollow fixed housing. A matrix of markers, or “fiducials”, are located in the wall of the housing. A single fiducial is located near the distal end of the moveable test rod. The distal end portion of the moveable test rod is adapted to be connected to a motion actuator, which is programmed to oscillate the test rod in a predetermined pattern. When the test unit sub-assembly is inserted into a tissue equivalent phantom member, the combined sub-assembly and phantom member can then be subjected to four-dimensional imaging to generate a visual image.

Abstract: The present invention is a thorax phantom that enables simulation of tumor motion within a tissue equivalent material. The system consists of a tissue equivalent epoxy phantom representing a 15 cm axial section of the human thorax that includes simplified spine and lung anatomies. Within the phantom are thru rods of similar tissue density. The rods are attached to a computer-controlled actuator that facilitates both linear and rotational motion of the rods within the phantom. A plurality of tumor targets and radiation detectors can be placed within the rods at various locations thereby enabling the simulation of respiratory and cardiac induced tumor motions within the phantom and assessment of the effects of these motions on image acquisitions, treatment planning and radiation treatment delivery.

Abstract: The present invention is a thorax phantom that enables simulation of tumor motion within a tissue equivalent material. The system consists of a tissue equivalent epoxy phantom representing a 15 cm axial section of the human thorax that includes simplified spine and lung anatomies. Within the phantom are thru rods of similar tissue density. The rods are attached to a computer-controlled actuator that facilitates both linear and rotational motion of the rods within the phantom. A plurality of tumor targets and radiation detectors can be placed within the rods at various locations thereby enabling the simulation of respiratory and cardiac induced tumor motions within the phantom and assessment of the effects of these motions on image acquisitions, treatment planning and radiation treatment delivery.